In the multiverse, you can live up to your ultimate potential. We discovered a way to temporarily link your consciousness to another version of yourself, accessing all of their memories and skills.
It's called verse jumping.
β Alpha Waymond
vrs is a personal software runtime - an opinionated take on my own "endgame" software platform.
Its goal is to turbocharge the development of my own software ecosystem. To this end, it considers every aspect of programming - language, execution, environment, and more - minimizing impedance over the end-to-end process of building software.
Its inspirations are Emacs, Erlang, Unix, Plan 9, and Hypermedia systems. It hopes to combine powerful ideas from those projects into one cohesive whole for an empowering, joyful, holistic programming experience.
The key principles are: joy, uniformity, simplicity, practicality, and interactivity.
π§ Under heavy construction π Here be dragons
vrs is a sandbox project, focused on play and experimentation in a pure-fun, pure-utility environment. While I live-on vrs everyday, the platform is very volatile in both concepts and implementation.
This software has rough edges. Be warned!
lyric: Embedded Lisp Dialect and Virtual Machinevrsd: A runtime implementation as a system daemonlibvrs: Thevrslibrary crate shared by runtime and client implementationsvrsctl: A thin CLI client overlibvrsvrsjmp: A GUI launch bar client
The runtime runs software written in Lyric lang:
# Use `def` to define new bindings
# e.g. "hello lyric!" string to symbol `msg`
(def msg "hello lyric!")
# Update bindings with `set`
(set msg "goodbye lyric!")
# Basic Primitives - integers, lists, keywords, and more
42 # integers
:my_keyword # keywords start with colon (:)
true # booleans are `true` or `false`
(list msg var_number var_keyword) # create new lists with `list` function
'("a" "b" "c") # quote expression with '
# Function declarationes use `defn`
# Lyric is expression-oriented - last form is returned as value to caller
(defn double (x)
(+ x x))
# Call functions by using bound symbol names within parens, followed by arguments
(double 10) # => 20
# List Operations
(def l '(1 2 3))
(def first (get l 0)) # get 0th item in `l`
(def last (get l -1)) # get last item in `l`
(contains? l 3) # check if `l` contains `3`
# Association Lists
(def item '(:title "My Title" :subtitle "My Subtitle"))
(get item :title) # => "My Title"
(get item :subtitle) # => "My Subtitle"
# Functions (Lambdas) are first class
(defn apply (x fn)
(fn x))
(apply 41 (lambda (x) (+ x 1))) # => 41
(map '(1 2 3) (lambda (x) (+ x x)) # => '(2, 4, 6)
# Conditionals with `if` - equality with `eq?`
(if (eq? msg "Hello")
"msg was hello"
"msg was not hello")
# and flip conditions with `not?`
(if (not? false)
"it was not true")
# Catch error with `try`. Introspect result with `err?` or `ok?`
(if (err? (try (not_a_function)))
"failed to call not_a_function")
# Pattern match with `match`. `_` is a wildcard pattern.
(def result '(:ok "Successful data"))
(match result
((:ok msg) msg)
((:err err) (:err err))
(_ '(:err "Unrecognized result")))
# Destructuring bindings can be used to pattern match against forms:
(def result '(:ok "Success"))
(def (:ok status) result) # matches :ok, binds status to string "Success"
# As a Lisp, Lyric has `eval` and `read`:
(eval (read "(+ 40 2)")) # => 42
# and there are more builtins and symbols in environment, introspectable via `ls_env` and `help`
(ls_env) # see all symbols defined in environment
(help recv) # see documentation via `help`
TODO: Examples for fibers, coroutines, yielding, infinite iterators, macros
In VRS, software runs as processes running Lyric lang.
These processes are implemented as green threads, and are lightweight compared to OS processes. Processes are scheduled on multiple cores using nonblocking IO.
Each process has a single logical thread of execution. CPU-bound and IO-bound work is transparent at process level, but the runtime schedules work such that a IO or CPU-bound work do not block cores.
While processes are preemptively scheduled, each process can create fibers, which can be used for cooperative multitasking, coroutines, infinite generators, etc within a single process.
Millions of processes can run on a single machine, without a single process halting the system altogether.
The low cost of processes allows it to serve as a single abstraction to simplify typical event-based, callback-based, or scheduling idioms used in building software.
For example, annual jobs can be represented as a infinite looping program that sleeps for a year:
(loop (sleep (duration :years 1))
(do_a_thing))
And user flows can be represented sequentially, without blocking the "main thread":
(def query (prompt "Enter search term: ")) # block on user response
(def items (search_items query)) # network-bound query
(def selection (select items)) # block on user selection
Processes run in isolated environments from one another - symbols bound in one process cannot be seen by another process. The only method for communicating between process is via message passing, covered below.
# See list of running processes in runtime
(ps)
# See this process's process_id
(self)
# Spawn a new process
(def echo_proc (spawn (lambda ()
(def (sender msg) (recv))
(send sender msg))))
Processes are isolated - and communicate through message-passing.
Each process has a dedicated mailbox that it can poll to receive messages:
# See messages in mailbox, without blocking or consuming a message
(ls_msgs)
# Poll for new message. This blocks execution until a message is received:
(recv)
# `recv` can poll for messages matching specific patterns
(recv '(:only_poll_for_matching msg))
# A common idiom is a "service loop" - an infinite loop that recv messages and runs some function within the process:
(loop (match (recv)
((:event_a ev) (handle_a ev))
((:event_b ev) (handle_b ev))
(_ (error "unexpected message"))))
# Sending messages is done via `(send PID MSG)`.
# Use process id from `(self)`, `(pid PID_NO)`, and `(find_srv SRV_NAME)`
(send (pid 10) :hello)
(send (self) :hello_from_self)
# Message from child back to parent
(def parent_pid (self))
(spawn (lambda ()
(sleep 10)
(send parent_pid :hello_from_child)))
Services are long-running processes that:
- are discoverable via name in service registry
- process messages in mailbox, which may update internal state, and respond to message sender
Processes (including services) can bind to another service, and communicate over message passing. There are convenience macros to help define message passing stubs between processes.
# `register` - register a process under name in service registry
(register :echo)
# `ls_srv` - Can list all services running within runtime
(ls_srv) # => ((:name :echo :pid <pid XX>))
# `find_srv` - Get PID for registered processes
(find_srv :echo) # => <pid XX>
# Register has options to overwrite and expose interfaces (as function names)
(defn ping (x) x)
(defn pong (y) y)
(register :service_c :interface '(ping pong) :overwrite)
# `srv` is a macro to:
# - Register process under a identifiable name in registry via `register`
# - Start a service loop (covered under "message passing")
(defn echo (msg) msg)
(srv :echo :interface '(echo))
# `srv` is blocking - but often it is more convenient to fork into a new service
# `spawn_srv` is a macro to expand into `srv` inside a `spawn` block:
(spawn_srv :echo :interface '(echo))
# `bind_srv` can be used to define matching message-passing stubs within another process to a service process:
(bind_srv :echo) # defines `(echo msg)` in current process, which messages `:echo` service
The runtime has built-in global pubsub mechanism.
# Subscribe to :my_topic
(subscribe :my_topic)
# Publish data to :my_topic
(publish :my_topic '(:hello :world))
# Updates are received via mailbox:
(recv) # => (:topic_updated :my_topic (:hello :world))
#!/usr/bin/env vrsctl
# Internal state in process - count
(def count 0)
# Define an interface to increment count and publish over topic
(defn increment (n)
(set count (+ count n))
(publish :count count))
# Serve a counter service, with `increment` as exported interface:
(spawn_srv :counter :interface '(increment))
#!/usr/bin/env vrsctl
# macOS System Appearance Integration
#
# Get system appearance state
(defn is_darkmode ()
(def (:ok result) (exec "osascript"
"-e" "tell application \"System Events\""
"-e" "tell appearance preferences"
"-e" "return dark mode"
"-e" "end tell"
"-e" "end tell"))
(eq? result "true"))
# Set system appearance state
(defn set_darkmode (dark)
(exec "osascript"
"-e" "on run argv"
"-e" "tell application \"System Events\""
"-e" "tell appearance preferences"
"-e" (if dark "set dark mode to true" "set dark mode to false")
"-e" "end tell"
"-e" "end tell"
"-e" "end run")
:ok)
# Toggle current state
(defn toggle_darkmode ()
(set_darkmode (not? (is_darkmode))))
# Fork into service exporting `toggle_darkmode` as service
(spawn_srv :system_appearance :interface '(toggle_darkmode))
vrsctl is a CLI client for vrs. When invoked without arguments, it launches into an interactive REPL useful for live programming and debugging:
$ vrsctl
# Experiment with lyric:
vrs> (def url "https://github.com/leoshimo/vrs")
"https://github.com/leoshimo/vrs"
vrs> (open_url url)
(:ok "")
# Introspect runtime state:
vrs> (ls_srv)
((:name :launcher :pid <pid 28> :interface ((:get_items) (:add_item title cmd)))
(:name :system_appearance :pid <pid 5> :interface ((:toggle_darkmode))))
# Bind and talk to services:
vrs> (bind_srv :launcher)
((:get_items) (:add_item title cmd))
vrs> (add_item "Hello" '(open_url "http://example.com"))
:okvrsctl also offers convenient interfaces and tools to support scripting and
debugging - see vrsctl --help for an overview of available commands.
There is an major-mode available for Emacs - lyric-mode.
It provides syntax highlighting and bindings useful for bottom-up, interactive, editor-centric software development.
The package is currently not available via package repositories - but is available in my dotfiles repository.